Albumin and mammalian cell culture: implications for biotechnology applications

Albumin has a long historical involvement in design of media for the successful culture of mammalian cells, in both the research and commercial fields. The potential application of albumins, bovine or human serum albumin, for cell culture is a by-product of the physico-chemical, biochemical and cell-specific properties of the molecule. In this review an analysis of these features of albumin leads to a consideration of the extracellular and intracellular actions of the molecule, and importantly the role of its interactions with numerous ligands or bioactive factors that influence the growth of cells in culture: these include hormones, growth factors, lipids, amino acids, metal ions, reactive oxygen and nitrogen species to name a few. The interaction of albumin with the cell in relation to these co-factors has a potential impact on metabolic and biosynthetic activity, cell proliferation and survival. Application of this knowledge to improve the performance in manufacturing biotechnology and in the emerging uses of cell culture for tissue engineering and stem cell derived therapies is an important prospect

Ets-2 is induced by oxidative stress and sensitizes cells to H2O2-induced apoptosis: Implications for Down's Syndrome

An elevated production of hydrogen peroxide mediates the increased rate of apoptosis of cells derived from individuals with Down's syndrome. The mechanism via which this occurs is unknown. Here we show that Ets-2, a transcription factor located on human chromosome 21 and already overexpressed in multiple tissues in Down syndrome (DS, trisomy 21), is induced by low concentrations of hydrogen peroxide. Moreover, cells with an imbalance in the antioxidant enzymes SOD-1/GPX-1, such as occurs in DS through the overexpression of the chromosome 21 gene SOD-1, also results in increased Ets-2 expression. The increase in Ets-2 expression is dependent on mRNA transcription. Importantly, we further demonstrate that 3T3 fibroblasts that overexpress Ets-2 are sensitized to hydrogen peroxide-induced apoptosis. These data implicate Ets-2 in the regulation of oxidant-induced apoptosis and provide a possible rationale for both the (5- to 7-) fold increase in Ets-2 protein level in DS tissues, above the expected gene dosage of 1.5-fold, and the elevated rate of apoptosis in DS cells

ETS2 overexpression in transgenic models and in Down syndrome predisposes to apoptosis via the p53 pathway

ETS2 is a transcription factor encoded by a gene on human chromosome 21 and alterations in its expression have been implicated in the pathophysiological features of Down syndrome (DS). This study demonstrates that overexpression of ETS2 results in apoptosis. This is shown in a number of circumstances, including ETS2-overexpressing transgenic mice and cell lines and in cells from subjects with DS. Indeed we report for the first time that the ETS2 overexpression transgenic mouse develops a smaller thymus and lymphocyte abnormalities similar to that observed in DS. In all circumstances of ETS2 overexpression, the increased apoptosis correlated with increased p53 and alterations in downstream factors in the p53 pathway. In the human HeLa cancer cell line, transfection with functional p53 enables ETS2 overexpression to induce apoptosis. Furthermore, crossing the ETS2 transgenic mice with p53-/- mice genetically rescued the thymic apoptosis phenotype. Therefore, we conclude that overexpression of human chromosome 21-encoded ETS2 induces apoptosis that is dependent on p53. These results have important consequences for understanding DS and oncogenesis and may provide new insights into therapeutic interventions

Overexpression of the chromosome 21 transcription factor Ets2 induces neuronal apoptosis

Down syndrome (trisomy 21) neurons display an increased rate of apoptosis in vitro. The genes on chromosome 21 that mediate this increased cell death remain to be elucidated. Here we show that the chromosome 21 transcription factor Ets2, a gene that is overexpressed in Down syndrome, is expressed in neurons, and that moderate overexpression of Ets2 leads to increased apoptosis of primary neuronal cultures from Ets2 tg mice that involves activation of caspase-3. Our data therefore suggest that overexpression of ETS2 may contribute to the increased rate of apoptosis of neurons in Down syndrome

A targeted NKX2.1 human embryonic stem cell reporter line enables identification of human basal forebrain derivatives

Stem cells & developmental biolog

NKX2-5eGFPw hESCs for isolation of human cardiac progenitors and cardiomyocytes

Stem cells & developmental biolog